Heat capacity
Encyclopedia : H : HE : HEA : Heat capacity
Heat capacity (usually denoted by a capital C, often with subscripts) is a measurable physical quantity that characterizes the ability of a body to store heat as it changes in temperature. It is defined as the rate of change of temperature as heat is added to a body at the given conditions and state of the body (foremost its temperature). In the International System of Units, heat capacity is expressed in units of joules per kelvin. It is termed an "extensive quantity" because it is sensitive to the size of the object (for example, a bathtub of water has a greater heat capacity than a cup of water). Dividing heat capacity by the body's mass yields a specific heat capacity (also called more properly "mass-specific heat capacity" or more loosely "specific heat"), which is an "intensive quantity," meaning it is no longer dependent on amount of material, and is now more dependent on the type of material, as well as the physical conditions of heating.
Definition
Heat capacity is mathematically defined as the ratio of a small amount of heat δQ added to the body, to the corresponding small increase in its temperature dT:
- [ C = \left( \frac \right)_ = T \left( \frac \right)_ ]
Heat capacity of compressible bodies
The state of a simple compressible body with fixed mass is described by two thermodynamic parameters such as temperature T and pressure P. Therefore as mentioned above, one may distinguish between heat capacity at constant volume, [C_V], and heat capacity at constant pressure, [C_P]:
- [C_V=\left(\frac\right)_V=T\left(\frac\right)_V ]
- [C_P=\left(\frac\right)_P=T\left(\frac\right)_P]
The increment of internal energy is the heat added and the work added:
- [dU=T\,dS-P\,dV]
- [C_V=\left(\frac\right)_V]
- [dH = dU + (PdV+VdP) \!] which at constant pressure (dP=0) reduces to:
- [dH=T\,dS+V\,dP.]
- [C_P=\left(\frac\right)_P. ]
Specific heat capacity
The specific heat capacity of a material is
- [c=]
- [c=c_m= = }]
- C is the heat capacity of a body made of the material in question (J·K−1)
- m is the mass of the body (kg)
- V is the volume of the body (m3)
- ρ = mV−1 is the density of the material (kg·m−3)
- [c_P=\left(\frac\right)_P]
- [c_V=\left(\frac\right)_V]
A related parameter to [c] is CV−1, the volumetric heat capacity, (J·m-3·K-1 in SI units). In engineering practice, [c_V] for solids or liquids often signifies a volumetric heat capacity, rather than a constant-volume one. In such cases, the mass-specific heat capacity (specific heat) is often explicitly written with the subscript m, as [c_m]. Of course, from the above relationships, for solids one writes:
- [c_m= = }]
Dimensionless heat capacity
The dimensionless heat capacity of a material is- [C^*= = }]
- C is the heat capacity of a body made of the material in question (J·K−1)
- n is the amount of matter in the body (mol)
- R is the gas constant (J·K−1·mol−1)
- nR=Nk is the amount of matter in the body (J·K−1)
- N is the number of molecules in the body. (dimensionless)
- k is Boltzmann's constant (J·K−1·molecule−1)
Theoretical models
Gas phase
According to the equipartition theorem from classical statistical mechanics, for a system made up of independent and quadratic degrees of freedom, any input of energy into a closed system composed of N molecules is evenly divided among the degrees of freedom available to each molecule. It can be shown that, in the classical limit of statistical mechanics, for each independent and quadratic degree of freedom, that
- [E_i=\frac]
[E_i] is the mean energy (measured in joules) associated with degree of freedom i.
T is the temperature (measured in Kelvin)
[k_B] is Boltzmann's constant, (1.380 6505(24) × 10−23 J K−1)
In the case of a monatomic gas such as helium under constant volume, if it assumed that no electronic or nuclear quantum excitations occur, each atom in the gas has only 3 degrees of freedom, all of a translational type. No energy dependence is associated with the degrees of freedom which define the position of the atoms. While, in fact, the degrees of freedom corresponding to the momenta of the atoms are quadratic, and thus contribute to the heat capacity. There are N atoms, each of which has 3 components of momentum, which leads to 3N total degrees of freedom. This gives:
- [C_V=\left(\frac\right)_V=\fracN\,k_B =\fracn\,R]
- [C_=\frac=\fracR = 1.5 R ]
[C_V] is the heat capacity at constant volume of the gas
[C_] is the molar heat capacity at constant volume of the gas
N is the total number of atoms present in the container
n is the number of moles of atoms present in the container (n is the ratio of N and Avogadro's number)
R is the ideal gas constant, (8.314570[70] J K−1mol−1). R is equal to the product of Boltzmann's constant [k_B] and Avogadro's number
The following table shows experimental molar constant volume heat capacity measurements taken for each noble monatomic gas (at 1 atm and 25 °C):
| Monatomic gas | CV, m (J K−1 mol−1) | CV, m / R |
|---|---|---|
| He | 12.5 | 1.50 |
| Ne | 12.5 | 1.50 |
| Ar | 12.5 | 1.50 |
| Kr | 12.5 | 1.50 |
| Xe | 12.5 | 1.50 |
It is apparent from the table that the experimental heat capacities of the monatomic noble gases agrees with this simple application of statistical mechanics to a very high degree. In the somewhat more complex case of an ideal gas of diatomic molecules, the presence of internal degrees of freedom are apparent. In addition to the three translational degrees of freedom, there are rotational and vibrational degrees of freedom. In general, the number of degrees of freedom, f, in a molecule with na atoms is 3na:
- [f=3n_a \,]
- [f_\mathrm=f-f_\mathrm-f_\mathrm=6-3-2=1 \,]
- [C_=\frac+R+R=\frac=3.5 R]
| Diatomic gas | CV, m (J K−1 mol−1) | CV, m / R |
|---|---|---|
| H2 | 20.18 | 2.427 |
| CO | 20.2 | 2.43 |
| N2 | 19.9 | 2.39 |
| Cl2 | 24.1 | 2.90 |
| Br2 | 32.0 | 3.84 |
From the above table, clearly there is a problem with the above theory. All of the diatomics examined have heat capacities that are lower than those predicted by the Equipartition Theorem, except [Br_2]. However, as the atoms composing the molecules become heavier, the heat capacities move closer to their expected values. One of the reasons for this phenomenon is the quantization of vibrational, and to a lesser extent, rotational states. In fact, if it is assumed that the molecules remain in their lowest energy vibrational state because the inter-level energy spacings are large, the predicted molar constant volume heat capacity for a diatomic molecule becomes
- [C_=\frac+R=\frac=2.5R]
Solid phase
For matter in a crystalline solid phase, the Dulong-Petit law, which was discovered empirically, states that the dimensionless specific heat capacity assumes the value 3. Indeed, for solid metallic chemical elements at room temperature, heat capacities range from about 2.8 to 3.4 (beryllium being a notable exception at 2.0).
The theoretical maximum heat capacity for larger and larger multi-atomic gases at higher temperatures, also approaches the Dulong-Petit limit of 3R, so long as this is calculated per mole of atoms, not molecules. The reason is that gases with very large molecules, in theory have almost the same high-temperature heat capacity as solids, lacking only the (small) heat capacity contibution that comes from potential energy that cannot be stored between separate molecules in a gas.
The Dulong-Petit "limit" results from the equipartition theorem, and as such is only valid in the classical limit of a microstate continuum, which is a high temperature limit. For light and non-metallic elements, as well as most of the common molecular solids based on carbon compounds at standard ambiant temperature, quantum effects may also play an important role, as they do in multi-atomic gases. These effects usually combine to give heat capacities lower than 3 R per mole of atoms in the solid, although heat capacities calculated per mole of molecules in molecular solids may be more than 3 R. For example, the heat capacity of water ice at the melting point is about 4.6 R per mole of molecules, but only 1.5 R per mole of atoms. The lower number results from the "freezing out" of possible vibration modes for light atoms at suitably low temperatures, just as in many gases. These effects are seen in solids more often than liquids: for example the heat capacity of liquid water is again close to the theoretical 3 R/mole of atoms of the Dulong-Petit theoretical maximum.
For a more modern and precise analysis of the heat capacities of solids, especially at low temperatures, it is useful to use the idea of phonons. See Debye model.
Heat capacity at absolute zero
From the definition of entropy
- [TdS=\delta Q\,]
- [S(T_f)=\int_^ \frac=\int_0^ \frac\frac=\int_0^ C(T)\,\frac]
See also
- Calorie
- Quantum statistical mechanics
- Specific heat capacity
- Heat capacity ratio
- Statistical mechanics
- Thermodynamic equations
- Volumetric heat capacity
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